GAS CHROMATOGRAPHY

KANHAIYA KUMAWAT

INTRODUCTION TO
CHROMATOGRAPHY
•Invention:
•By M.Twsettin 1906
•‘chroma’means color and ‘graphy’means writing
•Definition :
It is an instrumental method for separation and
identification of chemical compounds.
•Principle :
This technique is based on the difference in the rate at
which the components of a mixture move through a
porous medium (stationary phase) under the influence of
some solvent or gas (moving phase).

T=0
T=2 min
6 ft. long tube
Gas flow rate 3 ft. / min.
Gas flow rate 2 ft. / min.
T=0
T=3 min
Sand filled tube has some properties of GC column

Liquid “A” is non volatile
Dynamic Equilibrium
Gas B spends 40 % time in liquid phase

T=0
T=2 min
6 ft. long tube
Gas flow rate 3 ft. / min.
Gas flow rate 2 ft. / min.
T=0
T=3 min
T=0
T=5 min
(60/100) * 2 ft. / min. = 1.2 ft. / min. will be the flow rate.
•Gas B spend 60 % time in gaseous phase

•Gas C spend 80 % time in gaseous phase
(80/100) * 2 ft. / min. = 1.6 ft. / min. will be the flow rate.
T=0
T=3.75 min
R
t = 3.75
min.
faster
moving
less retained
R
t = 5 min.
slower
moving
more
retained
0 1 2 3 4 5 6 7
Time (minutes)
Detector Response

Gas C Gas B

T=10’
T=20’
T=0
Injector
Detector
Most Interaction with Stationary PhaseLeast
Flow of Mobile Phase

CLASSIFICATION OF
CHROMATOGRAPHIC METHODS
Chromatography
Partition Adsorption
(liquid stationary phase) (solid stationary phase)
Mobile Mobile Liquid Gaseous
Gaseous Liquid Mobile Mobile
Phase Phase Phase Phase
-GLC -HPLC -Column GSC
-Ion Exchange -Thin layer
-Paper

PARTITION TYPE
GLC (Gas-Liquid chromatography):
The separation is achieved due to difference in
solubilities and hence distribution of the solute
between liquid(stationary phase) and gaseous
phase(mobile phase).
HPLC (High pressure liquid chromatography):
In this high pressure is used to push a mobile phase
solution.
Ion Exchange:
It involves the exchange of ions between the
solution phase and inert solid material.

ADSORPTION TYPE
Column chromatography:
The mixture is dissolved in a suitable solvent and
passed through a tube containing adsorbent.
Paper chromatography:
The components of mixture are migrated at
different rates and appear as spots on paper.
Thin-Layer chromatography:
In this a thin layer of solid adsorbent is coated on
a glass or plastic plate.

In GAS CHROMATOGRAPHY
•The mobile phaseis an inert carrier gas.
•The stationary phaseis a solid or a liquid coated
on a solidcontained in a coiled column.

INSTRUMENTATION OF GAS
CHROMATOGRAPHY
•Operating principle of GC:
A sample is,
•Introduced into a injector port.
•Passed through column with inert carrier gas.
•Detected as a series of peaks by detector.

Experimental setup of GC

Carrier gas/
Regulator
Gas
Chromatograph
Computer Controls for
Method and Output

CARRIER GAS
•It is stored in gas cylinder under pressure.
•Its flow rate is controlled by two stage regulator.
•carrier gas should have following properties:
•Inert
•Suitable for detector and sample.
•Readily available in pure form.
•Cheap
•Best column performance with required
speed of analysis.
•Non explosive
•In GC H
2, He, and N
2are widely used as carrier
gas.
•Choice of Carrier Gas depends on sample to be
analyzed.

Thermal Conductivities Of Gases
3.68
3.18
CH
3OH
CH
4
3.96CO
2
6.24N
2
6.35O
2
11.6Ne
36.0He
44.5H
2
Thermal conductivity
cal/cm/
0
C/Sec.
Gas

SAMPLE INJECTION SYSTEM
•Sample:
•Pure, less quantity.
•It can be solid, liquid or gas.
•Prepared as a dilute solution.
•Sample injection system:
•It is one of the important part of GC.
•Sample is injected using a micro syringewhich enters
through a replaceable rubber septum (self sealing).
•As liquid sample is injected into a column it gets.
vaporized instantaneously so it enters in a column at
once.
•This system is temperature controlled.

Dilute
Solution
Pure
Sample

Column
•Columns are called as the brainof chromatograph.
•Generally used for the analytical purpose.
•Made up of glass or metal tube.
•Columns are usually placed in coiled form in a oven.
•There are two types of columns –
1) Packed column
2) Capillary columns
•Except columns all the components are same for
GLC and GSC.

Packed Columns
•Made up of glass or a metal tube having
–Diameter 1 to 8 mm.
–Length 2 to 20 meter.
•The number of theoretical plates are 20,000 or
more.
•Metal tube is packed with granular stationary phase.
•For GLC-Packing is prepared by coating a liquid
phase over an inert solid support.
•For GSC-Packed with size graded absorbent or a
porous polymer.

Efficiency of Chromatographic Column
•The efficiency of chromatographic column
is a measure of its ability to separatethe
components of a mixture.
•The efficiency of chromatographic column
is expressed in terms of number of
Theoretical plates, a term borrowed from
distillation process.

Efficiency of Column in terms of Theoretical plates.
No. of Theoretical plates, r = 16(x /y)
2
r = 16*(x/y)
2
= 16*((5-1)/0.5)
2
= 16(4/0.5)
2
= 16*64
= 1024
Theoretical plate height, H = L / r
= 6 ft./1024

Factors that affects theoretical plate height are discussed in
Van Deemtor equation
•H = A + B/V + CV
•Where,
•H is Theoretical plate height
•A = Depends on Eddy currents in flowing gas.
•B = Depends on diffusion of sample in gas phase and liquid phase. It is affected by
temperature.
•C = Depends on mass transfer of sample between two phases. (How fast the equilibrium
is achieved).
•V = Flow rate of the carrier gas.

Fig. A typical Van Deemter graph

Stationaryphase
In GLC, Support must satisfy the following properties-
•High surface area.
•Chemically inert.
•Material used as a support is crushed fire brickand used even in high
temperature furnaces for extended time periods.
•Surface of support is coated with liquid film, which is also chemically
inert and it’s vapor pressure must be low.
•Column packing is based on the type of the sample to be analyzed.
For Example,
•Carbowax 20 M(Polyethylene Glycol) is preferred for the
separation of alcohols, esters, pesticides and essence of oils.
•DEGadipate (Diethylene Glycol)column is used for the separation
of fatty acids, esters and pesticides.

Stationary phase
•For GSC, Use of porous polymer beads as a
packing material have certain advantages-
•Stable up to 250
0
C and causes no base line drift
and hence allows the use of the highly sensitive
detectors.
•no adsorption of polar components such as
water, alcohols, acids and are eluted rapidly as a
sharp symmetrical peaks.
•Sample overload recovery is rapid and without
trailing.
•Polymer beads are mechanically strong.
•Retention data are highly reproducible.
•Some of the separation provided are unique.

Column packing
•It is important that the packing is evenly done and
contains no gaps. Following method is used for the
packing of column:
Column is left uncoiled and held vertically on a
suitable plane. The column material is slowly added
to it from the top. In this way every time small
quantity of material is added and column is well
shaken.
At this stage the ultrasonic vibrator is used to vibrate
the column.
After packing, both the ends are sealed by glass wool.
Then the column is bent into a coil so that it will be
more compact for handling.
Now the column is ready to use in the instrument.

Capillary column
•These are also called as the open tabular columns.
•Made up of stainless steel, copper or a glass etc.
but stainless steel is most popular.
–Diameter is 0.25 to 0.75 mm.
–Length is 30 to 90 meter.
•Inside walls are coated with liquid phase in the
form of thin (0.5 to 1 micron) and uniform film.
•Number of theoretical plates are about several
100 to several 1000.
•Disadvantage –low capacity of resolution.
•It is very delicate.

Exit to
Detector
Enter from
Injector
Packed Column
installed in Oven
Compartment.

Temperature Programming in GC
•In order to get reproducible analytical results, it is
necessary to control the temperature of the column
very carefully. The low-boiling components are
eluted quickly and bunch together on the record
chart, while the less volatile species take much
longer and their peaks are much broader. This can
be overcome by increasing the temperature of the
column at a uniform rate.

Relation between the Retention time (Rt) and some parameters
Retention time (min.) Retention time (min.)0
5
10
15
20
25
30
35
0 50 100 150 200 250
temperature of a column (
0
C)
Retention Time (min.)

Qualitative analysis
•For a given column, if flow rate and temperature is
kept constant then the retention time data can be
highly reproducible and be used to identify the
compound.
•To check the quality of Product one has synthesized.
•To find the trace impurity if present in the sample.

Quantitative analysis
Quantitative analysisis based on the comparison of the area of the peak.
base
height h
W
Area = (Height * Base) / 2
Area = h * w

DETECTOR
•Function:To detect and measure different components
of sample as they emerge from column.
•Choice of detector depends upon type of analysis being
performed.
•Characteristics of an ideal detector :
•Rapid and reproducible response though quantity
of sample is less.
•Linear response over large concentration range.
•Good stability over entire temperature range.
•Uniform response to compounds of same
concentration having different chemical nature.
No single detector has all above characteristics.

•First family detectors:
•It responds to concentration
(in mole fraction) of solute.
•It do not destroys the
sample.
e.g Thermal conductivity
detector,
Electron capture detector,
Cross section detector,
Gas density balance,etc.
•Second family detectors :
•It responds to mass flow
rate of solute (in moles per
unit time).
•It destroys the sample.
e.g. Flame ionization detector,
Flame emission detector,
Microwave plasma detector,
Argon Ionization detector,
Helium Ionization detector

Thermal Conductivity Detector
•It belongs to first family detectors.
( Nondestructive detection technique)
•It is simple in construction.
•It is the most common.
•It is non selective i.e. Adequate sensitivity for many
compounds.
•It gives good linear range of signal.
•Signal is quite stable, provided carrier gas flow rate,
block temperature, and filament power are controlled.
•Principle : It is based on the difference between
the thermal conductivities of carrier gas and
sample.

Thermal Conductivity Detector

Thermal Conductivity Basics
When the carrier gas is contaminated by
sample , the cooling effect of the
gas changes. The difference in cooling
is used to generate the detector signal.
The TCD is a nondestructive,
concentration sensing detector. A
heated filament is cooled by the flow
of carrier gas .
Flow Flow

Unequal loss of heat from filament
•When a compound elutes, the thermal
conductivity of the gaseous mixture of carrier gas
and compound gas is lowered, and the filament in
the sample column becomes hotter than the other
control column.
•Its resistance increased, and this imbalance
between control and sample filament resistances is
measured by a simple gadget and a signal is
recorded.

•For maximum sensitivity, change in resistivity
should be large. Hence carrier gas of high thermal
conductivityis used.
•H
2, Hehas thermal conductivity 6 to 10 times
that of most organic compound. But they are
hazardous and costly.
•N
2,Co
2has same order of thermal conductivity
as that of most organic compound. They are
cheap and non hazardous.
•TCD is not most sensitive but satisfactory for a
wide variety of analytical applications.

ELECTRON CAPTURE
DETECTOR
•It is non destructive in nature.
•It has extreme sensitivity.
•It is selective in nature, i.e. it is insensitive
to amines,alcohols and hydrocarbons and
sensitive to halogen compounds,compounds
containing functional groups like nitro
group, peroxides, quinone.
Principle:Decrease in ion current due to
presence of sample.

ELECTRON CAPTURE DETECTOR
Ni-63
β-Ray electron

Flame Ionization Detector
•It is destructive in nature.
•It is one of the most sensitive detector.
•It is 1000 times sensitive than TCD.
•It is sensitive to all hydrocarbons and hetero-organic
compounds.
•Insensitive to many inorganic compounds.
•It is superior for quantitative analysis.

Detectors Sensitivity Linear rangeComments
Thermal conductivity 10
-8
10
4
Universal sensitivity
nondestructive
Flame ionization 10
-11
10
6
Detects all organic
compounds, the most
widely used GC
detector
Electron capture 10
-13
10
2
Detector Halo, Nitro and
Oxygenated
compound response
varies significantly
non destructive

•The detector information can also sent to electronic
devices where it is amplified and plotted against time.
This is called as chromatograph.

Analysis of Data
•Each component of the mixture reaches the detector at
a different time and produces a signal at a
characteristic time called a retention time.
•In the printout of the chromatographic analysis:
•the number of peakscorrelates with the number
of componentsin the sample,
•the area under each peakcorrelates with the
relative amount of that componentin the sample,
•and if standard information is available, the
retention timeunder defined conditions can be
used to identifyeach component.

CHROMATOGRAPH :
A plot of detectors response VS Time is called as
Chromatograph
Response
Retention Time, in min.
X
X
X
1
2
1
0
4 7

R
t = 3.0 min.
faster moving
less retained
R
t = 5.6 min.
slower moving
more retained
Approximation
of peak area by
triangulation
Area =
base x height
2
base
height
0 1 2 3 4 5 6 7
Time (minutes)
Absorbance

Peak A Peak B

TENTATIVE IDENTIFICATION OF UNKNOWN
COMPOUNDS
Response
GC Retention Time
Standard response for X
1.6 min = RT
Response
GC Retention Time
Standard response for Y
3.2 min = RT
Response
GC Retention Time
Sample having three components
1.6 min = RT
3.2 min = RT

MAIN ADVANTAGES OF GC
•Strong separation power
•High sensitivity
•Good precision and accuracy
•Short time analysis
•Low cost and long life
•Easy to handle: does not require highly
qualified person.

THANK YOU
for hearing me patiently

Response
GC Retention Time
Good Separation
Response
GC Retention Time
Poor Separation
Back

Van Deemter Equation
•H = A + B/V + CV
Where,
H is Theoretical plate height
A = Depends on Eddy currentsin flowing gas.
B = Depends on diffusionof sample in gas phase and liquid
phase. It is affected by temperature.
C = Depends on mass transfer of sample between two phases
V = Flow rate of the carrier gas.

R
t = 3.75 min.
faster moving
less retained
R
t = 5 min.
slower moving
more retained
0 1 2 3 4 5 6 7
Time (minutes)
Detector Response

Gas C Gas B

GAS CHROMATOGRAPHY

About This Presentation

Slide Content

Tags

Categories

Download

Quick Actions

Statistics

Related Slideshows

GAS CHROMATOGRAPHY

About This Presentation

Slide Content

Slide 1

Slide 2

Slide 4

Slide 5

Slide 6

Slide 7

Slide 8

Slide 9

Slide 10

Slide 11

Slide 12

Slide 13

Slide 14

Slide 15

Slide 16

Slide 17

Slide 18

Slide 19

Slide 21

Slide 22

Slide 23

Slide 24

Slide 25

Slide 26

Slide 27

Slide 29

Slide 30

Slide 31

Slide 33

Slide 34

Slide 35

Slide 36

Slide 37

Slide 38

Slide 39

Slide 40

Slide 41

Slide 43

Slide 44

Slide 45

Slide 46

Slide 47

Slide 48

Slide 50

Slide 51

Slide 52

Slide 53

Slide 54

Slide 55

Slide 56

Slide 57

Slide 59

Slide 60

Slide 61

Tags

Categories

Download

Quick Actions

Statistics

Related Slideshows

Earthquakes_Type of Faults_Science G8.pptx

Quiz #1 Science 10 in the first quarter for jhs

Astronomy history from long ago till doday

Great history of astronomy from long ago till today

EARTHQUAKE-DRILL.powerpoint.............

History of astronomy from old times to the present times